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scsh/ccp.scm
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scsh/ccp.scm
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;;; Char->char partial maps -*- Scheme -*-
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;;; Copyright (C) 1998 by Olin Shivers.
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;;; CCPs are an efficient data structure for doing simple string transforms,
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;;; similar to the kinds of things you would do with the tr(1) program.
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;;;
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;;; This code is tuned for a 7- or 8-bit character type. Large, 16-bit
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;;; character types would need a more sophisticated data structure, tuned
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;;; for sparseness. I would suggest something like this:
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;;; (define-record ccp
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;;; domain ; The domain char-set
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;;; map ; Sorted vector of (char . string) pairs
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;;; ; specifying the map.
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;;; id?) ; If true, mappings not specified by MAP are
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;;; ; identity mapping. If false, MAP must
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;;; ; specify a mapping for every char in DOMAIN.
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;;;
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;;; A (char . string) elements in MAP specifies a mapping for the contiguous
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;;; sequence of L chars beginning with CHAR (in the sequence of the underlying
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;;; char type representation), where L is the length of STRING. These MAP elements
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;;; are sorted by CHAR, so that binary search can be used to get from an input
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;;; character C to the right MAP element quickly.
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;;;
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;;; This representation should be reasonably compact for standard mappings on,
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;;; say, a Unicode CCP. An implementation might wish to have a cache field
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;;; in the record for storing the full 8kb bitset when performing ccp-map
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;;; operations. Or, an implementation might want to store the Latin-1 subset
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;;; of the map in a dense format, and keep the remainder in a sparse format.
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(define num-chars (char-set-size char-set:full)) ; AKA 256.
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(define-record ccp
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domain ; The domain char-set
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dshared? ; Is the domain value shared or linear?
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map ; 256-elt string
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mshared?) ; Is the map string shared or linear?
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;;; Accessors and setters that manage the linear bookkeeping
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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(define (ccp-domain ccp)
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(set-ccp:dshared? ccp #t)
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(ccp:domain ccp))
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;;; CCP is a linear ccp. PROC is a domain->domain function; it must be
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;;; linear in its parameter and result.
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;;;
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;;; Updates the domain of the CCP with PROC, returns the resulting
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;;; CCP; reuses the old one to construct the new one.
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(define (restrict-linear-ccp-domain ccp proc)
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(let ((new-d (proc (if (ccp:dshared? ccp)
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(begin (set-ccp:dshared? ccp #f)
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(char-set-copy (ccp:domain ccp)))
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(ccp:domain ccp)))))
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(set-ccp:domain ccp new-d)
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ccp))
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;;; CCP is a linear CCP. PROC is a domain x cmap -> domain function.
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;;; It is passed a linear domain and cmap string. It may side-effect
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;;; the cmap string, and returns the resulting updated domain.
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;;; We return the resulting CCP, reusing the parameter to construct it.
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(define (linear-update-ccp ccp proc)
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(let* ((cmap (if (ccp:mshared? ccp)
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(begin (set-ccp:mshared? ccp #f)
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(string-copy (ccp:map ccp)))
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(ccp:map ccp)))
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(new-d (proc (if (ccp:dshared? ccp)
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(begin (set-ccp:dshared? ccp #f)
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(char-set-copy (ccp:domain ccp)))
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(ccp:domain ccp))
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cmap)))
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(set-ccp:domain ccp new-d)
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ccp))
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;;; Return CCP's map field, and mark it as shared. CCP functions that
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;;; restrict a ccp's domain share map strings, so they use this guy.
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(define (ccp:map/shared ccp)
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(set-ccp:mshared? ccp #t)
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(ccp:map ccp))
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(define (ccp-copy ccp) (make-ccp (char-set-copy (ccp:domain ccp)) #f
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(string-copy (ccp:map ccp)) #f))
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;;; N-ary equality relation for partial maps
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(define (ccp= ccp1 . rest)
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(let ((domain (ccp:domain ccp1))
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(cmap (ccp:map ccp1)))
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(every (lambda (ccp2)
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(and (char-set= domain (ccp:domain ccp2))
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(let ((cmap2 (ccp:map ccp2)))
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(char-set-every? (lambda (c)
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(let ((i (char->ascii c)))
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(char=? (string-ref cmap i)
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(string-ref cmap2 i))))
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domain))))
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rest)))
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;;; N-ary subset relation for partial maps
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(define (ccp<= ccp1 . rest)
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(let lp ((domain1 (ccp:domain ccp1))
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(cmap1 (ccp:map ccp1))
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(rest rest))
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(or (not (pair? rest))
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(let* ((ccp2 (car rest))
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(domain2 (ccp:domain ccp2))
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(cmap2 (ccp:map ccp2))
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(rest (cdr rest)))
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(and (char-set<= domain1 domain2)
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(let ((cmap2 (ccp:map ccp2)))
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(char-set-every? (lambda (c)
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(let ((i (char->ascii c)))
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(char=? (string-ref cmap1 i)
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(string-ref cmap2 i))))
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domain1))
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(lp domain2 cmap2 rest))))))
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;;; CCP iterators
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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(define (ccp-fold kons knil ccp)
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(let ((cmap (ccp:map ccp)))
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(char-set-fold (lambda (c v) (kons c (string-ref cmap (char->ascii c)) v))
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knil
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(ccp:domain ccp))))
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(define (ccp-for-each proc ccp)
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(let ((cmap (ccp:map ccp)))
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(char-set-for-each (lambda (c) (proc c (string-ref cmap (char->ascii c))))
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(ccp:domain ccp))))
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(define (ccp->alist ccp)
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(ccp-fold (lambda (from to alist) (cons (cons from to) alist))
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'()
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ccp))
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;;; CCP-RESTRICT
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Restrict a ccp's domain.
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(define (ccp-restrict ccp cset)
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(make-ccp (char-set-intersection cset (ccp:domain ccp))
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#f
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(ccp:map/shared ccp)
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#t))
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(define (ccp-restrict! ccp cset)
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(restrict-linear-ccp-domain ccp (lambda (d) (char-set-intersection! d cset))))
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;;; CCP-ADJOIN ccp from-char1 to-char1 ...
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;;; CCP-DELETE ccp char1 ...
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Add & delete mappings to/from a ccp.
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(define (ccp-delete ccp . chars)
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(make-ccp (apply char-set-delete (ccp:domain ccp) chars)
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#f
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(ccp:map/shared ccp)
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#t))
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(define (ccp-delete! ccp . chars)
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(restrict-linear-ccp-domain ccp (lambda (d) (apply char-set-delete! d chars))))
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(define (ccp-adjoin ccp . chars)
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(let ((cmap (string-copy (ccp:map ccp))))
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(make-ccp (install-ccp-adjoin! cmap (char-set-copy (ccp:domain ccp)) chars)
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#f
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cmap
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#f)))
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(define (ccp-adjoin! ccp . chars)
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(linear-update-ccp ccp (lambda (d cmap) (install-ccp-adjoin! cmap d chars))))
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(define (install-ccp-adjoin! cmap domain chars)
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(let lp ((chars chars) (d domain))
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(if (pair? chars)
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(let ((from (car chars))
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(to (cadr chars))
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(chars (cddr chars)))
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(string-set! cmap (char->ascii from) to)
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(lp chars (char-set-adjoin! d from)))
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d)))
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;;; CCP-EXTEND ccp1 ...
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;;; CCP-EXTEND! ccp1 ccp2 ...
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Extend ccp1 with ccp2, etc.
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(define (ccp-extend . ccps)
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(if (pair? ccps)
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(let ((ccp0 (car ccps))
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(ccps (cdr ccps)))
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(if (pair? ccps)
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(let ((cmap (string-copy (ccp:map ccp0)))) ; Copy cmap.
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;; The FOLD installs each ccp in CCPS into CMAP and produces
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;; the new domain.
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(make-ccp (fold (lambda (ccp d)
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(install-ccp-extension! cmap d ccp))
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(char-set-copy (ccp:domain ccp0))
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ccps)
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#f cmap #f))
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ccp0)) ; Only 1 parameter
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ccp:0)) ; 0 parameters
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(define (ccp-extend! ccp0 . ccps)
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(linear-update-ccp ccp0
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(lambda (domain cmap)
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(fold (lambda (ccp d) (install-ccp-extension! cmap d ccp))
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domain
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ccps))))
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;;; Side-effect CMAP, linear-update and return DOMAIN.
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(define (install-ccp-extension! cmap domain ccp)
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(let ((cmap1 (ccp:map ccp))
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(domain1 (ccp:domain ccp)))
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(char-set-for-each (lambda (c)
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(let ((i (char->ascii c)))
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(string-set! cmap i (string-ref cmap1 i))))
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domain1)
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(char-set-union! domain domain1)))
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;;; Compose the CCPs. 0-ary case: (ccp-compose) = ccp:1.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; For each character C-IN in the original domain, we push it
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;;; through the pipeline of CCPs. If we ever land outside the
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;;; domain of a ccp, we punt C-IN. If we push it all the way
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;;; through, we add C-IN to our result domain, and add the mapping
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;;; into the cmap we are assembling.
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;;;
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;;; Looping this way avoids building up intermediate temporary
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;;; CCPs. If CCP's were small bitsets, we might be better off
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;;; slicing the double-nested loops the other way around.
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(define (ccp-compose . ccps)
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(cond ((not (pair? ccps)) ccp:1) ; 0 args => ccp:1
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((not (pair? (cdr ccps))) (car ccps)) ; 1 arg
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(else
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(let* ((v (list->vector ccps))
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(vlen-2 (- (vector-length v) 2))
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(cmap (make-string num-chars))
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(d1 (ccp:domain (vector-ref v (+ vlen-2 1))))
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(d (char-set-fold (lambda (c-in d)
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(let lp ((c c-in) (i vlen-2))
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(if (>= i 0)
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(let ((ccp (vector-ref v i)))
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(if (char-set-contains? (ccp:domain ccp) c)
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(lp (string-ref (ccp:map ccp)
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(char->ascii c))
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(- i 1))
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;; Lose: remove c-in from d.
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(char-set-delete! d c-in)))
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;; Win: C-IN -> C
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(begin (string-set! cmap
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(char->ascii c-in)
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c)
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d))))
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(char-set-copy d1)
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d1)))
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(make-ccp d #f cmap #f)))))
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;;; ALIST->CPP
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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(define (alist->ccp cc-alist . maybe-base-ccp)
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(let ((base (:optional maybe-base-ccp ccp:0)))
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(if (pair? cc-alist)
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(let ((cmap (string-copy (ccp:map base))))
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(make-ccp (install-ccp-alist! cmap
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(char-set-copy (ccp:domain base))
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cc-alist)
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#f cmap #f))
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base)))
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(define (alist->ccp! alist base)
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(linear-update-ccp base (lambda (d cmap) (install-ccp-alist! cmap d alist))))
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;;; Side-effect CMAP, linear-update and return DOMAIN.
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(define (install-ccp-alist! cmap domain alist)
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(fold (lambda (from/to d) (let ((from (car from/to))
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(to (cdr from/to)))
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(string-set! cmap (char->ascii from) to)
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(char-set-adjoin! domain from)))
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domain
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alist))
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;;; PROC->CCP
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; (proc->ccp proc [domain base-ccp])
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(define (proc->ccp proc . args)
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(let-optionals args ((proc-domain char-set:full)
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(base ccp:0))
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(let ((cmap (string-copy (ccp:map base))))
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(make-ccp (install-ccp-proc! cmap (char-set-copy (ccp:domain base))
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proc proc-domain)
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#f cmap #f))))
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(define (proc->ccp! proc proc-domain base)
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(linear-update-ccp base
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(lambda (d cmap) (install-ccp-proc! cmap d proc proc-domain))))
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(define (install-ccp-proc! cmap domain proc proc-domain)
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(char-set-for-each (lambda (c) (string-set! cmap (char->ascii c) (proc c)))
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proc-domain)
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(char-set-union! domain proc-domain))
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;;; CONSTANT-CCP
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; (constant-ccp char [domain base-ccp])
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;;; Extend BASE-CCP with the a map taking every char in DOMAIN to CHAR.
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;;; DOMAIN defaults to char-set:full. BASE-CCP defaults to CCP:0.
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(define (constant-ccp char . args)
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(let-optionals args ((char-domain char-set:full) (base ccp:0))
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(let ((cmap (string-copy (ccp:map base))))
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(make-ccp (install-constant-ccp! cmap (char-set-copy (ccp:domain base))
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char char-domain)
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#f cmap #f))))
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(define (constant-ccp! char char-domain base)
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(linear-update-ccp base
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(lambda (d cmap) (install-constant-ccp! cmap d char char-domain))))
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;;; Install the constant mapping into CMAP0 by side-effect,
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;;; linear-update & return DOMAIN0 with the constant-mapping's domain.
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(define (install-constant-ccp! cmap0 domain0 char char-domain)
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(char-set-for-each (lambda (c) (string-set! cmap0 (char->ascii c) char))
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char-domain)
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(char-set-union! domain0 char-domain))
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;;; CCP/MAPPINGS
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; (ccp/mappings from1 to1 from2 to2 ...) -> ccp
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;;; (extend-ccp/mappings base-ccp from1 to1 from2 to2 ...) -> ccp
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;;; (extend-ccp/mappings! base-ccp from1 to1 from2 to2 ...) -> ccp
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;;; Each FROM element is either a string or a (lo-char . hi-char) range.
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;;; Each TO element is either a string or a lo-char. Strings are replicated
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;;; to match the length of the corresponding FROM element.
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;;; CCP/MAPPINGS's base CCP is CCP:0
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;;;
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;;; Tedious code.
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;;; Internal utility.
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;;; Install the FROM->TO mapping pair into DOMAIN & CMAP by side-effect.
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;;; Return the new domain.
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(define (install-ccp-mapping-pair! cmap domain from to)
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;; Tedium -- four possibilities here:
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;; str->str, str->lo-char,
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;; range->str, range->lo-char.
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(if (string? from)
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(if (string? to)
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;; "abc" -> "ABC"
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(let ((len1 (string-length from))
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(len2 (string-length to)))
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(let lp2 ((i (- len1 1))
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(j (modulo (- len2 1) len1))
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(d domain))
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(if (>= i 0)
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(let ((c (string-ref from i)))
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(string-set! cmap
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(char->ascii c)
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(string-ref to i))
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(lp2 (- i 1)
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(- (if (> j 0) j len2) 1)
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(char-set-adjoin! d c)))
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d)))
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;; "abc" -> #\A
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(let lp2 ((i (- (string-length from) 1))
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(j (char->ascii to))
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(d domain))
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(if (>= i 0)
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(let ((c (string-ref from i)))
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(string-set! cmap
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(char->ascii c)
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(ascii->char j))
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(lp2 (- i 1)
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(- j 1)
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(char-set-adjoin! d c)))
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d)))
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(let ((from-start (char->ascii (car from)))
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(from-end (char->ascii (cdr from))))
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(if (string? to)
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(let ((len2-1 (- (string-length to) 1)))
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;; (#\a . #\c) -> "ABC"
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(let lp2 ((i from-start) (j 0) (d domain))
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(if (<= i from-end)
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(let ((c (string-ref to j)))
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(string-set! cmap i c)
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(lp2 (+ i 1)
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(if (= j len2-1) 0 (+ j 1))
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(char-set-adjoin! d c)))
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d)))
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;; (#\a . #\c) -> #\A
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(do ((i from-start (+ i 1))
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(j (char->ascii to) (+ j 1))
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(d domain (begin (string-set! cmap i (ascii->char j))
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(char-set-adjoin d (ascii->char i)))))
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((> i from-end) d))))))
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;;; Internal utility -- side-effects CMAP; linear-updates & returns DOMAIN.
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||||
(define (install-mapping-pairs cmap domain args)
|
||||
(let lp ((domain domain) (args args))
|
||||
(if (pair? args)
|
||||
(lp (install-ccp-mapping-pair! cmap domain (car args) (cadr args))
|
||||
(cddr args))
|
||||
domain)))
|
||||
|
||||
(define (ccp/mappings . args)
|
||||
(let ((cmap (make-string num-chars)))
|
||||
(make-ccp (install-mapping-pairs (make-string num-chars)
|
||||
(char-set-copy char-set:empty)
|
||||
args)
|
||||
#f cmap #f)))
|
||||
|
||||
(define (extend-ccp/mappings base . args)
|
||||
(let ((cmap (string-copy (ccp:map base))))
|
||||
(make-ccp (install-mapping-pairs cmap (char-set-copy (ccp:domain base)) args)
|
||||
#f cmap #f)))
|
||||
|
||||
(define (extend-ccp/mappings! base . args)
|
||||
(linear-update-ccp base (lambda (d cmap) (install-mapping-pairs cmap d args))))
|
||||
|
||||
|
||||
;;; CONSTRUCT-CCP! ccp elt ...
|
||||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||||
;;; The kitchen-sink constructor; static typing be damned.
|
||||
;;; ELTS are interpreted as follows:
|
||||
;;; (lo-char . hi-char) to-string|lo-char ; ccp/range
|
||||
;;; from-string to-string|lo-char ; ccp/range
|
||||
;;; ccp ; ccp-extend
|
||||
;;; alist ; alist->ccp
|
||||
;;; domain char ; ccp-constant
|
||||
;;; domain proc ; proc->ccp
|
||||
|
||||
(define (construct-ccp! ccp . elts)
|
||||
(linear-update-ccp ccp (lambda (d cmap) (install-ccp-construct! cmap d elts))))
|
||||
|
||||
(define (construct-ccp base . elts)
|
||||
(let ((cmap (string-copy (ccp:map base))))
|
||||
(make-ccp (install-ccp-construct! cmap (char-set-copy (ccp:domain base)) elts)
|
||||
#f cmap #f)))
|
||||
|
||||
;;; Install the mappings into CMAP by side-effect,
|
||||
;;; linear-update & return DOMAIN with the final domain.
|
||||
|
||||
(define (install-ccp-construct! cmap domain elts)
|
||||
(let lp ((d domain) (elts elts))
|
||||
;(format #t "d=~s elts=~s\n" d elts)
|
||||
(if (not (pair? elts)) d
|
||||
(let ((elt (car elts))
|
||||
(elts (cdr elts)))
|
||||
(cond ((pair? elt)
|
||||
(cond ((pair? (car elt)) ; ELT is an alist.
|
||||
(lp (install-ccp-alist! cmap d elt) elts))
|
||||
((char? (car elt)) ; ELT is (lo-char . hi-char) range.
|
||||
(lp (install-ccp-mapping-pair! cmap d elt (car elts))
|
||||
(cdr elts)))
|
||||
(else (error "Illegal elt to construct-ccp" elt))))
|
||||
|
||||
((string? elt)
|
||||
(lp (install-ccp-mapping-pair! cmap d elt (car elts))
|
||||
(cdr elts)))
|
||||
|
||||
((ccp? elt) (lp (install-ccp-extension! cmap d elt) elts))
|
||||
|
||||
((char-set? elt)
|
||||
(let ((elt2 (car elts))
|
||||
(elts (cdr elts)))
|
||||
(lp (cond ((char? elt2)
|
||||
(install-constant-ccp! cmap d elt2 elt))
|
||||
((procedure? elt2)
|
||||
(install-ccp-proc! cmap d elt2 elt))
|
||||
(else (error "Illegal elt-pair to construct-ccp"
|
||||
elt elt2)))
|
||||
elts)))
|
||||
|
||||
(else (error "Illegal elt to construct-ccp" elt)))))))
|
||||
|
||||
|
||||
;;; CCP unfold
|
||||
|
||||
(define (ccp-unfold p f g seed)
|
||||
(let lp ((seed seed) (ccp (ccp-copy ccp:0)))
|
||||
(if (p seed) ccp
|
||||
(lp (g seed)
|
||||
(receive (from to) (f seed)
|
||||
(lp (g seed) (ccp-adjoin! ccp from to)))))))
|
||||
|
||||
|
||||
|
||||
;;; Using CCPs
|
||||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||||
;;; TR ccp string [start end] -> string
|
||||
;;; CCP-MAP ccp string [start end] -> string
|
||||
;;; CCP-MAP! ccp string [start end] -> undefined
|
||||
;;; CCP-APP ccp char -> char or false
|
||||
|
||||
;;; If a char in S is not in CCP's domain, it is dropped from the result.
|
||||
;;; You can use this to map and delete chars from a string.
|
||||
|
||||
(define (tr ccp s . maybe-start+end)
|
||||
(let-optionals maybe-start+end ((start 0) (end (string-length s)))
|
||||
;; Count up the chars in S that are in the domain,
|
||||
;; and allocate the answer string ANS:
|
||||
(let* ((len (- end start))
|
||||
(domain (ccp:domain ccp))
|
||||
(ans-len (string-fold (lambda (c numchars)
|
||||
(if (char-set-contains? domain c)
|
||||
(+ numchars 1)
|
||||
numchars))
|
||||
0 s start end))
|
||||
(ans (make-string ans-len)))
|
||||
|
||||
;; Apply the map, installing the resulting chars into ANS:
|
||||
(string-fold (lambda (c i) (cond ((ccp-app ccp c) =>
|
||||
(lambda (c)
|
||||
(string-set! ans i c)
|
||||
(+ i 1)))
|
||||
(else i))) ; Not in domain -- drop it.
|
||||
0 s start end)
|
||||
ans)))
|
||||
|
||||
(define (ccp-map ccp s . maybe-start+end)
|
||||
(apply string-map (lambda (c) (ccp-app ccp c)) s maybe-start+end))
|
||||
|
||||
(define (ccp-map! ccp s . maybe-start+end)
|
||||
(apply string-map! (lambda (c) (ccp-app ccp c)) s maybe-start+end))
|
||||
|
||||
(define (ccp-app ccp char)
|
||||
(and (char-set-contains? (ccp:domain ccp) char)
|
||||
(string-ref (ccp:map ccp) (char->ascii char))))
|
||||
|
||||
|
||||
;;; Primitive CCPs
|
||||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||||
|
||||
(define id-cmap
|
||||
(let ((m (make-string num-chars)))
|
||||
(do ((i (- num-chars 1) (- i 1)))
|
||||
((< i 0))
|
||||
(string-set! m i (ascii->char i)))
|
||||
m))
|
||||
|
||||
(define ccp:0 (make-ccp char-set:empty #t id-cmap #t))
|
||||
(define ccp:1 (make-ccp char-set:full #t id-cmap #t))
|
||||
|
||||
(define ccp:upcase (proc->ccp char-upcase char-set:full))
|
||||
(define ccp:downcase (proc->ccp char-downcase char-set:full))
|
Loading…
Reference in New Issue